JPH10123556A - Liquid crystal display device and tape carrier package for it - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid crystal display device and a tape carrier package for it capable of simplifying and facilitating arrangement work of wiring for drawing a distortion voltage, hardly being affected by an external noise and surely suppressing cross talk. SOLUTION: A distortion voltage detection electrode 16 electrically equivalent to a scan electrode related to the distortion voltage is provided on a liquid crystal panel 100. Bridging pattern wiring 51 in non-connect to a scanning drive IC 45y is provided on the tape carrier package 300 loading the scanning drive IC 45y. A voltage correction circuit 29 is loaded on a printed circuit board 200 loading a scan electrode source circuit 22, and pattern wiring 33 from the voltage correction circuit 29 is formed on the printed circuit board 200 to be connected to the input side detection terminal 49 of the bridging pattern wiring 51. The end part 16a of the distortion voltage detection electrode 16 is connected to the output side detection terminal 50 of the bridging pattern wiring 51.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display panel, a printed circuit board on which a power supply circuit and the like are mounted, and a liquid crystal driving device.
The present invention relates to a liquid crystal display device comprising a tape carrier package (TCP) mounting C and bridging between the liquid crystal display panel and a printed circuit board, and a tape carrier package for such a liquid crystal display device.

[0002]

2. Description of the Related Art Liquid crystal display devices are widely used as information processing devices such as word processors and personal computers, and as display devices such as small televisions and projection televisions, taking advantage of their features such as thinness and low power consumption.
Liquid crystal display elements for such applications are roughly classified into two types: a simple matrix type and an active matrix type.

A simple matrix type liquid crystal display device has a simple structure including a liquid crystal display panel portion as a whole, and can be easily manufactured up to a large one at a low manufacturing cost. Have been.

In recent years, STN (Super Twisted
The number of pixels (the number of row electrodes × the number of column electrodes) of a simple matrix type liquid crystal display panel represented by a nematic) type liquid crystal display element (panel) has increased remarkably, and the driving frequency of the liquid crystal display panel has accordingly increased. Is getting higher.

Generally, a liquid crystal cell for each pixel of a liquid crystal display panel can be represented as a capacitor in an equivalent circuit. Also, a liquid crystal drive I for driving the liquid crystal display panel is provided.
C has an output impedance, which can be generally expressed as an electrical resistance in an equivalent circuit. Simple matrix liquid crystal display elements are driven by a combination of square wave pulses. At this time, the output impedance of the liquid crystal drive IC, the connection resistance between the liquid crystal drive IC and the liquid crystal display panel, the electrode resistance for driving the liquid crystal display panel, etc. And the capacitance of the liquid crystal layer causes distortion or dullness in the drive voltage waveform. That is, the waveform of the voltage applied to the scanning electrode (row electrode) is distorted by induction from the high-frequency signal voltage waveform applied to the signal electrode (column electrode), or is formed by an electric resistance and a capacitor. This causes waveform dulling due to the distributed constant circuit. These distortions and dullness of the drive voltage waveform cause a decrease or increase in the voltage applied to the liquid crystal layer, and as a result, are referred to as positional variations of light transmittance in the screen of the liquid crystal display panel, that is, crosstalk. It appears on the screen as a phenomenon of display unevenness.

[0006] In the simple matrix type liquid crystal display panel, the most involved in the generation of crosstalk is the fluctuation of the liquid crystal applied voltage due to the distortion voltage generated in the scanning electrode due to the induction from the high frequency signal voltage waveform. Reducing the distortion voltage generated in the scanning electrodes leads to suppression of crosstalk.

Some proposals have recently been made on methods for reducing the distortion voltage generated in the scanning electrodes. For example, the Journal of the Institute of Television Engineers of Japan Vol.47, No.5, pp610-615 (199
3) "Method of driving crosstalk reduction of simple matrix LCD", JP-A-6-180564, JP-A-7-180564
No. 84554 and the like.

The outline of the method of generating and suppressing these crosstalks is as follows. A scanning non-selection waveform (potential V _com ) applied to the scan electrode (row electrode) in synchronization with a high-frequency signal voltage waveform applied to the signal electrode (column electrode)
, A spike-like distortion voltage is generated (see FIG. 6C). This distortion voltage is generated by being induced from the signal voltage waveform applied to the column electrode via the capacitance of the liquid crystal. When a spike-like distortion voltage is generated in the scanning electrode, the effective voltage of the liquid crystal applied voltage applied to the liquid crystal layer changes. Such a change in the effective voltage differs depending on the phase of the signal voltage waveform (square wave) applied to the signal electrode. In other words, there are pixels that change in the direction in which the voltage increases and pixels that change in the direction in which the voltage decreases depending on the display image.
This is seen as a variation in light transmittance in the screen of the liquid crystal display panel. This is display unevenness called crosstalk.

As described above, in synchronization with the signal voltage waveform applied to the signal electrode, a spike-like distortion voltage (see FIG. 6 (c)) generated in the scan non-selection waveform induced by the scan electrode is generated. In order to reduce this distortion voltage, in each of the above-mentioned documents, one end of the distortion voltage extraction wiring is connected to the open end of the scanning electrode opposite to the power supply side. The other end of the distortion voltage extracting wiring is connected to an inverting input terminal of an operational amplifier for applying a voltage to the scanning electrode, and the detected distortion voltage is negatively fed back to the power supply circuit. The distortion voltage extraction wiring is connected to the inverting input terminal of the operational amplifier via a DC component cutting capacitor and an amplification factor setting resistor, and the operational amplifier, the capacitor, and the resistor constitute a voltage correction circuit. I have. The power supply circuit and the voltage correction circuit are mounted on a printed circuit board. Alternatively, in the liquid crystal display panel, a strip-shaped scanning electrode voltage detection unit which opposes the open side end of all the scanning electrodes with the liquid crystal layer interposed therebetween in the same manner as the signal electrodes is disposed in parallel with the signal electrodes, One end of a strain voltage extracting wiring (indicated by reference numeral 500 in FIG. 1) is connected to the end of the scanning electrode voltage detecting section in the same manner as described above, and the other end of the distortion voltage extracting wiring is connected to the scanning electrode by a voltage. Is connected to the inverting input terminal of the operational amplifier in the voltage correction circuit for applying the negative voltage, and the detected distortion voltage is negatively fed back to the power supply side.

In this case, the operational amplifier in the voltage correction circuit calculates the difference between the negatively fed-back distortion voltage and the scanning voltage output to the scanning electrode, and applies the difference voltage to the scanning electrode to thereby perform scanning. Negative feedback control of the electrode voltage is performed. Thereby, the distortion voltage that is induced by the scanning electrode can be reduced, and the crosstalk is suppressed.

[0011]

However, in each of the above documents, the open-side end of each scan electrode in a liquid crystal display panel or the end of a scan electrode voltage detector and a voltage correction circuit on a printed circuit board are disclosed. No specific description is given as to how to specifically arrange the strain voltage extraction wiring for connecting. It is merely depicted as one element in a circuit diagram.

The problem here is that if the wiring for drawing out the strain voltage is to be arranged by using a wiring material such as a jumper wire, the wiring material must be prepared, and a wiring work such as soldering and a wiring work are required. Extra work such as routing is required, which leads to an increase in man-hours and an increase in cost. Also,
If a wiring material such as a jumper wire is used, the length of the wiring becomes longer, and external noise is more likely to be received.Therefore, the detected distortion voltage is buried in the noise, so that the distortion voltage cannot be accurately corrected and the crosstalk is suppressed. Leave a problem with.

The present invention has been made in view of such circumstances, and can simplify and simplify the operation of arranging wiring for drawing out a distortion voltage necessary for suppressing crosstalk. It is another object of the present invention to provide a liquid crystal display device and a tape carrier package for a liquid crystal display device which can minimize the influence of external noise by making the wiring as short as possible and reliably suppress crosstalk.

[0014]

According to a first aspect of the present invention, there is provided a liquid crystal display device in which a plurality of scanning electrodes and a plurality of signal electrodes are opposed to each other in a matrix in a state of being orthogonal to each other, and a liquid crystal cell is provided at each intersection. A liquid crystal display panel, a printed circuit board on which an electrode voltage power supply circuit is mounted, and a bridge between the liquid crystal display panel and the printed circuit board, connected to the output side of the electrode voltage power supply circuit and connected to the scan electrode. A tape carrier package mounted with a liquid crystal drive IC to be connected, and a distortion voltage induced in a scan electrode in a non-selection period due to a signal voltage waveform immediately outside the scan electrode group in the liquid crystal display panel. An electrode voltage power supply, which is provided with a strain voltage detecting electrode which is electrically equivalent to the scanning electrode and is parallel to the scanning electrode, and supplies a voltage to the scanning electrode on the printed circuit board; In the liquid crystal display device to which the voltage correction circuit is provided which said distortion voltage induced distortion voltage to the detecting electrode type negative feedback manner with respect to the road to correct the supply voltage, the liquid crystal drive I on said tape carrier package
The end of the distortion voltage detection electrode of the liquid crystal display panel on the tape carrier package side is connected to the bridging pattern wiring formed from the input edge to the output edge in a state of being disconnected from C. A pattern wiring connected to the voltage correction circuit on the printed board is connected to the bridging pattern wiring on the tape carrier package. In a liquid crystal display panel, a strain voltage detection electrode electrically equivalent to a scan electrode with respect to a strain voltage is provided in parallel with the scan electrode, and the strain voltage detection electrode is not connected to the liquid crystal drive IC on the tape carrier package. Is connected to the voltage correction circuit via the, so compared to the conventional technology that connected a distortion voltage extraction wiring such as a jumper wire to the open side end of the scanning electrode, routed it and connected to the voltage correction circuit Since the routing is virtually eliminated and is hardly affected by extraneous noise, there is no problem that the detected distortion voltage is buried in extraneous noise as in the case of jumpers, etc., where the routing tends to be long. In addition, it is possible to accurately correct the distortion voltage and reliably suppress the crosstalk. In addition, there is no need to prepare wiring materials such as jumper wires, and there is no need for complicated wiring work and wiring work for the scanning electrode open side end and voltage correction circuit, and the tape carrier package for the liquid crystal display panel is eliminated. Since the strain voltage detecting electrode can be connected to the bridging pattern wiring at the same time as the bonding, there is no unnecessary increase in the number of steps and no cost increase.

According to a second aspect of the present invention, there is provided a tape carrier package for a liquid crystal display device, wherein a plurality of scanning electrodes and a plurality of signal electrodes are arranged in a matrix so as to be orthogonal to each other, and a liquid crystal cell is arranged at each intersection. In addition, a distortion voltage detection electrode that is electrically equivalent to the scan electrode and is parallel to the scan electrode is disposed immediately outside the scan electrode group for a distortion voltage induced in the scan electrode during the non-selection period due to the signal voltage waveform. A liquid crystal display panel, an electrode voltage power supply circuit for supplying a voltage to the scanning electrodes, and a negative feedback input of the distortion voltage induced by the distortion voltage detection electrode to the electrode voltage power supply circuit to correct the supply voltage. This bridges the printed circuit board on which the voltage correction circuit is mounted, and is connected to the output side of the electrode voltage power supply circuit on the tape carrier and the input of the scanning electrode. A tape carrier package on which a liquid crystal drive IC connected to the liquid crystal display panel is mounted, wherein the tape carrier has an input side detection terminal for connecting to a pattern wiring connected to a voltage correction circuit of the printed circuit board, and a tape carrier package. The present invention is characterized in that a bridging pattern wiring is formed so as not to be connected to the liquid crystal drive IC between an output side detection terminal for connection to an end of the distortion voltage detection electrode. When connecting the distortion voltage detection electrode provided on the liquid crystal display panel and the voltage correction circuit provided on the printed circuit board in a state in which the induced distortion voltage is electrically equivalent to the scanning electrode, an electrode voltage power supply circuit of the printed circuit board In the liquid crystal display device tape carrier package itself, which mounts a liquid crystal drive IC connecting the scanning electrodes of the liquid crystal display panel to the printed circuit board and the liquid crystal display panel, via the bridging pattern wiring formed on the tape carrier. To connect the strain voltage detection electrode and the voltage correction circuit. By using this tape carrier package for a liquid crystal display device, when assembling a printed circuit board and a liquid crystal display panel to manufacture a liquid crystal display device, a wiring for drawing out a distortion voltage such as a jumper wire is connected to the open side end of the scanning electrode. Compared to the conventional technology that connected the voltage correction circuit, the wiring is virtually eliminated and there is almost no influence from external noise. As in the case, the problem that the detected distortion voltage is buried in external noise is eliminated, the distortion voltage can be accurately corrected, the crosstalk can be reliably suppressed, and wiring materials such as jumper wires are prepared. It is not necessary, and complicated connection of wiring materials to the scan electrode open side end and voltage correction circuit This eliminates the need for any work or wiring routing work, and the strain voltage detection electrode can be connected to the bridging pattern wiring at the same time as the bonding of the tape carrier package to the liquid crystal display panel. No.

According to a third aspect of the present invention, there is provided a tape carrier package for a liquid crystal display device according to the second aspect, wherein a liquid crystal drive is applied to an input side detection terminal for connection to a pattern wiring connected to a voltage correction circuit of a printed circuit board. It is characterized in that a plurality of output-side detection terminals are provided, which are connected to the IC via a bridging pattern wiring in a disconnected state and are connected to the end of the distortion voltage detection electrode of the liquid crystal display panel. Since there are multiple output-side detection terminals, the junction area with the end of the distortion voltage detection electrode can be increased, the contact resistance is reduced, and the induced distortion voltage is further reduced, and the voltage correction in the voltage correction circuit is more accurate. Thus, crosstalk caused by the distortion voltage can be prevented with higher accuracy.

According to a fourth aspect of the present invention, there is provided a tape carrier package for a liquid crystal display device according to the second aspect, wherein the output side detection terminal connected to the end of the distortion voltage detection electrode of the liquid crystal display panel has an alignment mark. It is characterized in that it is also used as a dummy terminal for positioning in the vicinity. By using the output side detection terminal also as the positioning dummy terminal, it is possible to realize a simple and inexpensive structure for suppressing crosstalk.

According to a fifth aspect of the present invention, there is provided a tape carrier package for a liquid crystal display device according to the second to fourth aspects.
In any one of the above, the entire structure including the liquid crystal driving IC is symmetrical. Depending on the model, there are those that connect to the liquid crystal display panel with the liquid crystal drive IC on the front side and those that connect with the liquid crystal drive IC on the back side.
Either the front side or the back side can be selected and used with the liquid crystal drive IC mounted, which simplifies the work of arranging the wiring for extracting the distortion voltage required for suppressing the crosstalk described above. At the same time, the wiring can be made as short as possible to make it less susceptible to external noise, and the effect of reliably suppressing crosstalk can be exhibited.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, specific embodiments of the liquid crystal display device according to the present invention will be described in detail with reference to the drawings.

[First Embodiment] FIG. 1 is a circuit diagram showing a schematic circuit configuration of a liquid crystal display device according to a first embodiment. This liquid crystal display device is roughly divided into a liquid crystal display panel 100, a printed circuit board 200 (200a, 200b) on which a power supply circuit and a voltage correction circuit are mounted, and a plurality of tapes bridging the liquid crystal display panel 100 and the printed circuit board 200. And a carrier package (TCP) 300. In the present embodiment, the printed circuit board 200
Although the printed circuit board 200a on the scanning side and the printed circuit board 200b on the signal side are divided into two pieces, it is needless to say that a single printed circuit board may be integrated.

The liquid crystal display panel 100 is roughly composed of two glass substrates 11 and 13 arranged facing each other,
A plurality of parallel scanning electrodes 12 formed as thin films on the inner surface of one glass substrate 11 along the X direction (horizontal direction).
On the inner surface of the other glass substrate 13 in the Y direction (vertical direction).
A plurality of parallel signal electrodes 1 formed as thin films along
4, and a liquid crystal filled between the glass substrates 11 and 13. The individual scanning electrodes 12 and the individual signal electrodes 14 cross and face each other in a vertical posture, and a liquid crystal is interposed therebetween. The intersections are individually referred to as liquid crystal cells. Since the intersections can be equivalently represented by capacitance, they are shown with a capacitor symbol and are shown as liquid crystal cells 15. Reference numeral 16 denotes a distortion voltage detection electrode which is electrically equivalent to the scan electrode 12 with respect to the distortion voltage, which is a feature of the present invention, and will be described later in detail.

A power supply circuit 21, a scan electrode power supply circuit 22, a signal electrode power supply circuit 23 and the like are mounted on the printed circuit board 200a on the scanning side. Scan electrode power supply circuit 22
Is provided with a voltage dividing circuit 24 and three buffers 25, 26, and 27 using an operational amplifier (operational amplifier). The buffer 25 has a higher scanning selection voltage V as the scanning selection voltage.
_H , the buffer 26 outputs a neutral scanning non-selection voltage _Vcom , and the buffer 27 outputs a lower scanning selection voltage _VL . The voltage dividing circuit 24 is connected to the output terminal of the power supply circuit 21 and the buffers 25,
The non-inverting input terminals (+) of 26 and 27 are connected to each resistance dividing point of the voltage dividing circuit 24. The non-inverting input terminal (+) of the buffer 26 that outputs the scanning non-selection voltage V _com is connected to a resistance dividing point connected to the ground GND. The signal electrode power supply circuit 23, whose internal configuration is not shown, has substantially the same configuration. That is, it includes a voltage dividing circuit connected to the output terminal of the power supply circuit 21 and a buffer using two operational amplifiers that output the higher selection voltage V + and the lower selection voltage V−. The signal electrode power supply circuit 23 is connected to the signal-side printed circuit board 200b via a wiring 28. Reference numeral 29 denotes a buffer 26 which outputs the scanning non-selection voltage V _com in order to reduce the detected distortion voltage by connecting the aforementioned distortion voltage detection electrode 16 which is a feature of the present invention.
This is a voltage correction circuit for correcting the output voltage of the power supply, which will be described later.

The printed circuit board 200a on the scanning side and the printed circuit board 200b on the signal side are connected to the liquid crystal display panel 100 via a plurality of tape carrier packages 300, respectively. The scanning drive IC 45y is mounted on the tape carrier package 300 on the scanning side, and the output terminals of the buffers 25, 26, and 27 of the scan electrode power supply circuit 22 are connected to the input port side of the scanning drive IC 45y. Each scanning electrode 12 # of the liquid crystal display panel 100 is connected to the output port side of the IC 45y as shown. A signal driving IC 45x is mounted on the signal side printed circuit board 200b.
The output terminal of each buffer of the signal electrode power supply circuit 23 is connected to the input port side (not shown in this connection state), and each signal electrode 14 of the liquid crystal display panel 100 is connected to the output port side of the signal driving IC 45x. ‥ are connected as shown. The specific configuration of the tape carrier package 300 will be described later in detail.

Attention is now focused on one horizontal scanning electrode 12. It is assumed that a scanning pulse 91 of the higher scanning selection voltage V _H shown in FIG. 6A is applied to a frame corresponding to one screen display with respect to the target scanning electrode 12. Then, only this target scanning electrode 12 is in the active state, and all the remaining scanning electrodes 12 # remain in the inactive state. During the application of the scanning pulse 91, when a signal voltage (drawn in a sufficiently small time span) is sequentially applied to all the signal electrodes 14 # as data, the signal electrode 14 # is connected to the target scanning electrode 12. Liquid crystal cell 15 # is driven according to the signal voltage waveform.
That is, a difference voltage between the scanning selection voltage _VH and the higher selection voltage V + or the lower selection voltage V- is applied to each liquid crystal cell 15 # as an effective voltage, and each liquid crystal cell 15 # is driven by this effective voltage. Is done. During the period of the pulse width of the scanning pulse 91, the same number of signal voltages as the number of all the signal electrodes 14 # are output.

Next, after the application of the scanning pulse 91, the scanning voltage for the target scanning electrode 12 enters the non-selection period T ₀ ,
The voltage applied to the target scanning electrode 12 is a scanning non-selection voltage V
_com . In the non-selection period T ₀ of the target scan electrode 12, a scan pulse (not shown) of the scan selection voltage V _H is sequentially applied to the remaining scan electrodes 12 #. Then, when a certain scanning electrode 12 other than the target scanning electrode 12 is active, as described above, if a signal voltage as data is sequentially applied to all the signal electrodes 14 #, The liquid crystal cell 1 connected to one scan electrode 12 that is now active
5 ° is driven according to the signal voltage waveform. Similarly, when all the remaining scanning electrodes 12 # are active, a signal voltage as data is sequentially applied to all the signal electrodes 14 #. FIG Thus remaining signal voltage waveforms for all the scan electrodes 12 ‥ except interest scanning electrode 12 is in the non-selection period T ₀ 6
It is a signal voltage waveform shown to (b). This signal voltage waveform is also schematically illustrated. Specifically, one component of the rectangular signal voltage waveform at the non-selection period T ₀ in FIG. 6 (b), but in fact is comparable to the number of all the signal electrodes 14 ‥, one rectangular pulse of this Are schematically shown as representatives. The time width Ts ′ of the representative rectangular pulse is the same as the pulse width Ts of the scanning pulse 91. Such rectangular waves are shown for [the number of scanning electrodes minus one] in one frame period (some parts in the middle are omitted). One is drawn with a fine span corresponding to the scanning pulse 91. That is, FIG. 6A shows the scanning electrode 1 of interest.
6 shows a scan voltage waveform, and FIG. 6B shows a set of signal voltage waveforms for all scan electrodes 12 # other than the scan electrode 12 of interest.

In this one frame period (period from V _H to V _L ), the lower selection voltage V−
Turns on the liquid crystal cell 15, and the higher selection voltage V + turns off the liquid crystal cell 15. When one frame period ends and the next inversion frame period starts, the voltage of the scan pulse 92 for activating the scan electrode 12 is inverted to the lower scan selection voltage _VL . This is because the liquid crystal deteriorates early if a scanning pulse of a single polarity is always applied. However, the higher scanning selection voltage _VH and the lower scanning selection voltage _VL alternate every frame. This is for preventing the deterioration of the liquid crystal by applying the voltage. This is the polarity inversion driving method. In the polarity inversion driving method, during the inversion frame period in which the voltage of the scanning pulse 92 becomes the lower scanning selection voltage V _L , the higher selection voltage V + is applied to the liquid crystal cell 1 conversely.
5 is turned on, and the lower selection voltage V− turns off the liquid crystal cell 15.

As described above, the number of pixels (the number of scanning electrodes.times.the number of signal electrodes) of a simple matrix type liquid crystal display panel typified by an STN (super twisted nematic) type liquid crystal display panel is significantly increased. Accordingly, the driving frequency of the liquid crystal display panel is also increased, and the frequency of the signal voltage waveform is particularly high. The liquid crystal cell 15 is equivalently a capacitance, and a scanning driving IC
45y has an output impedance, a connection resistance between the IC and the liquid crystal display panel 100, and a driving electric resistance of the liquid crystal display panel 100. Due to the presence of the capacitance component and the resistance component, the signal electrode 14 # If the frequency of the applied signal voltage waveform is high, a distortion voltage is generated in each scanning electrode 12 by induction. That is, as shown in FIG. 6 (c), by the induction of signal voltage waveform when the scan electrodes 12 ‥ except interest scan electrodes 12 is active, scanning the focused scan electrodes 12 in the non-selection period T ₀ Spike-shaped distortion voltage waveforms are generated above and below the non-selection voltage _Vcom . Then, when a distortion voltage is generated in the target scanning electrode 12 in the non-selection period T ₀ , the target scanning electrode 12 in the non-selection period T ₀ , which should be originally inactive,
A drive level voltage is applied to the liquid crystal cell 15 connected to the
In other words, the variation of the light transmittance within the screen 0, that is, a phenomenon of display unevenness called crosstalk, appears on the screen. In the above description, the target scanning electrode 12
Are considered as one, but in practice, the scanning pulse 91
There is only for only one of the scan electrodes 12 in one horizontal scanning period being applied, the rest of all the scanning electrodes 12 ‥ in a non-selection period T _0, the remainder all the scan electrodes 12 ‥ , The above-mentioned crosstalk occurs.

Here, in order to advance the understanding, the problems in the conventional technology are pointed out again.

[0029] Although the crosstalk due to the distortion voltage generated in the scanning non-selection voltage V _com of the scan electrodes 12 during the non-selection period T ₀ by induction from a high frequency of the signal voltage waveform is generated, the cross-talk In order to suppress this, a distortion voltage is detected, and the detected distortion voltage is
2 that outputs the scanning non-selection voltage V _com
Conventionally, negative feedback is made to 6. A voltage correction circuit 29 in the scan electrode power supply circuit 22 is provided for that purpose. The voltage correction circuit 29 includes a DC component cutting capacitor 30 and amplification factor setting resistors 31 and 32.
The series circuit of the capacitor 30 and the resistor 31 is connected to the inverting input terminal (-) of the buffer 26. The operational amplifier constituting the buffer 26 calculates the difference between the negatively fed-back distortion voltage and the scan voltage output to the scan electrode 12, and applies the difference voltage to the scan electrode 12. Is controlled by negative feedback, thereby reducing the distortion voltage induced in the scan electrode 12 and suppressing the crosstalk.

However, in the prior art, in order to detect a distortion voltage induced in the scan electrode 12, the open side end 12a opposite to the power supply side of the scan electrode 12 is used.
Is connected to a distortion voltage extraction wiring 500 such as a jumper wire as shown by a virtual line (two-dot chain line), and the other end of the distortion voltage extraction wiring 500 is connected to the input side of the capacitor 30 of the voltage correction circuit 29. Connection, extra work such as soldering between the strain voltage extraction wiring 500 and the scanning electrode open side end 12a and the terminal of the capacitor 30 and extra work such as wiring routing are required, and the number of man-hours is increased. Not only does this lead to an increase in cost, but also the length of the strain voltage extraction wiring 500 is inevitably lengthened, and the strain voltage detected is buried in the noise because it is susceptible to external noise. Therefore, it was difficult to sufficiently suppress crosstalk.

In the liquid crystal display device according to the first embodiment of the present invention, it is possible to simplify the operation of arranging the wiring for extracting the distortion voltage necessary for suppressing the crosstalk and to reduce the wiring. In order to minimize crosstalk by making it as short as possible and making it less susceptible to external noise, the following contrivance has been made.

It utilizes a pattern wiring for bridging on a tape carrier package 300 for bridging and connecting the liquid crystal display panel 100 and the printed circuit board 200a on the scanning side.

FIG. 2 shows a tape carrier package (TC
3 is a plan view showing the configuration of P) 300. FIG. A large number of input terminal groups 42 # are formed along one side of the tape carrier 41, and a large number of output terminal groups 43 # are formed along the opposite side.
45, an input pad and an output pad are connected to an input terminal group 42 # and an output terminal group 43 # via an inner lead 46 and pattern wirings 47 and 48, respectively.
A liquid crystal drive IC 45 is mounted on the tape carrier 41. Input side detection terminals 49 not connected to the liquid crystal drive IC 45 are arranged on both sides of the input terminal group 42 #, and output side detection terminals 50 not connected to the liquid crystal drive IC 45 are arranged on both sides of the output terminal group 43 #. Each input-side detection terminal 49 and output-side detection terminal 50 are connected via a bridging pattern wiring 51. Tape carrier 41
At the left and right ends of the output side of the tape carrier package 3
Positioning marks 52 are provided for positioning when the LCD 00 is connected to the liquid crystal display panel 100, and two positioning dummy terminals 53 are provided.

When the tape carrier package 300 is connected to the liquid crystal display panel 100, the positioning mark 52 of the tape carrier package 300 and the positioning dummy terminal 53 inside the tape carrier package 300 are connected to the corresponding one of the liquid crystal display panel 100 under a microscope. The alignment between the output terminal group 43 # on the tape carrier package 300 side and the multiple scan electrode group 12 # or the signal electrode group 14 # on the liquid crystal display panel 100 side can be performed without aligning the bonding tool. By pressing and heating by applying a pulse current (pulse heat), the two are electrically and mechanically joined via an anisotropic conductive adhesive. Similarly, the tape carrier package 300 is electrically and mechanically joined to the printed circuit boards 200a and 200b via an anisotropic conductive adhesive or by solder connection. Note that, in FIG. 1, the symbol notation of the liquid crystal driving IC 45 indicates that the scanning drive I
C45y, and a signal drive IC 45x in the tape carrier package 300 bridged to the printed circuit board 200b on the signal side. Although the circuit configurations of the scanning drive IC 45y and the signal drive IC 45x are generally different, the same configuration may be used.

The tape carrier package 300 is symmetrical. This is so that the liquid crystal driving IC 45 can be used even if it is turned upside down with the liquid crystal driving IC 45 mounted. Depending on the model, there are a type that is connected to the liquid crystal display panel 100 with the liquid crystal driving IC 45 on the front side, and a type that is connected with the liquid crystal driving IC 45 on the back side.
In order to deal with this, it is symmetrical. In addition, although the scanning order of the liquid crystal driving IC 45 is reversed due to the upside down,
This is adjusted by switching the switch so that the scanning order is normal.

Returning to FIG. 1, in the liquid crystal display device according to the first embodiment of the present invention, in order to detect a distortion voltage generated in scan electrode 12, liquid crystal display panel 100 is used.
Is provided with a strain voltage detection electrode 16 on the uppermost side thereof. The distortion voltage detection electrode 16 is connected to the liquid crystal display panel 10.
0 in the same manner as the scanning electrode 12 in the manufacturing process. For example, in the case of a liquid crystal display panel of 480 lines × 600 dots, the scanning electrodes 12 are increased by one line.
81 are formed, and the uppermost scanning electrode is used as the distortion voltage detecting electrode 16. No scanning voltage is applied to the distortion voltage detection electrode 16. However, the strain voltage detection electrode 16 is electrically equivalent to the scan electrode 12 with respect to a strain voltage induced in the scan electrode 12 by a high-frequency signal voltage waveform. That is, as in the case of the scanning electrode 12, the distortion voltage detecting electrode 16 and all the signal electrodes 14
‥ is connected to the liquid crystal cell 15 、, and the distortion voltage waveform induced to the distortion voltage detection electrode 16 via the liquid crystal cell 15 に よ っ て by the signal voltage waveform is the distortion voltage waveform induced to the scanning electrode 12. And the same waveform. However, since the scanning voltage is not applied to the distortion voltage detection electrode 16, the liquid crystal cell 1 connected to the distortion voltage detection electrode 16
5 ‥ does not perform a display operation. In order to make the distortion voltage detection electrode 16 electrically equivalent to the scanning electrode 12, the distortion voltage detection electrode 16 and all the signal electrodes
Is connected to the liquid crystal cell 15 #. Needless to say, the distortion voltage detection electrode 16 is the scanning electrode group 1
It is parallel to 2 ‥.

With respect to the induced distortion voltage, the scanning electrode 12
Voltage detection electrode 1 provided in a state electrically equivalent to
6 is an end 1 on the tape carrier package 300 side.
At 6a, it is electrically and mechanically connected to the output side detection terminal 50 of the tape carrier package 300 via an anisotropic conductive adhesive. The detailed state is shown in FIG. As described above, in the tape carrier package 300, the output side detection terminal 50 is connected to the input side detection terminal 49 via the bridging pattern wiring 51 in advance. The input side detection terminal 49 is connected to the pattern wiring 33 formed in advance on the scanning side printed circuit board 200a via an anisotropic conductive adhesive or solder. Bonding of the end portion 16a of the distortion voltage detection electrode 16 to the output side detection terminal 50 is performed simultaneously when bonding the output terminal group 43 # of the tape carrier package 300 to the scanning electrode group 12 # of the liquid crystal display panel 100, Also, the pattern wiring 33
Of the input-side detection terminal 49 is simultaneously performed when the input terminal group 42 # of the tape carrier package 300 is connected to the output terminal group of the scan electrode power supply circuit 22 of the printed circuit board 200a on the scan side.

The tape carrier package 300 on the signal side printed circuit board 200b is used as the tape carrier package 300 on the scanning side printed circuit board 200a.
Similarly to the above, the tape carrier package 300 is used in which the output-side detection terminal 50 and the input-side detection terminal 49 not connected to the scanning drive IC 45y are connected by the bridging pattern wiring 51. A conventional tape carrier package without the above may be used for the printed circuit board 200b on the signal side.

The distortion voltage shown in FIG. 6C induced from the high-frequency signal voltage waveform through the liquid crystal cell 15 に 対 し て with respect to the scanning electrode 12 in the non-selection period T ₀ shown in FIG. Substantially the same strain voltage is also induced in the strain voltage detection electrode 16. This distortion voltage is applied to the voltage correction circuit 2 via the bridging pattern wiring 51 on the tape carrier package 300 and the pattern wiring 33 on the printed circuit board 200a.
9 and a DC component cutting capacitor 30 and a resistor 3
1, an inverting input terminal (-) of a buffer 26 that outputs a scanning non-selection voltage _Vcom composed of a differential amplification operational amplifier.
, The buffer 26 calculates the difference between the scanning non-selection voltage V _com input from the voltage dividing circuit 24 and the distortion voltage input in the negative feedback, and corrects the difference voltage to the corrected scanning non-selection voltage V _com Output as FIG. 6D shows the corrected waveform of the scanning non-selection voltage _Vcom . FIG. 6 (c)
Is sufficiently reduced as compared with the induced distortion voltage shown in FIG. 1 and is lower than the level for driving the liquid crystal cell 15 #, so that the liquid crystal cell 15 # is not unexpectedly driven, resulting in display unevenness. Crosstalk is surely suppressed.

In the first embodiment of the present invention, when the line for connecting the distortion voltage detection electrode 16 to the voltage correction circuit 29 is provided, the distortion voltage detection electrode 16
LCD panel 100 provided with a voltage correction circuit 29
The bridge pattern wiring 51 connecting the output side detection terminal 50 and the input side detection terminal 49 of the tape carrier package 300 bridging the scanning side printed circuit board 200a provided with the pattern wiring 33 on the printed circuit board 200a. The distortion voltage detection electrode 16 is connected to the voltage correction circuit 2
9, the wiring is substantially eliminated as compared with the case where the wiring is connected by the strain voltage extracting wiring 500 shown by a two-dot chain line such as a jumper line connected to the open side end 12a of the scanning electrode 12, Since it is hardly affected by extraneous noise, there is no problem that the detected distortion voltage is buried in extraneous noise as in the case of jumper wires, etc., and the distortion voltage is accurately corrected to suppress crosstalk. You can do it. In addition, troublesome connection work and wiring routing work in the case of a jumper wire or the like are not required, and the strain voltage detection electrode 16 is connected to the bridging pattern wiring 5 at the same time as the bonding of the tape carrier package 300 to the liquid crystal display panel 100.
Since it can be connected to one, there is no wasted man-hour increase and no cost increase.

[Second Embodiment] In the liquid crystal display device of the first embodiment, the tape carrier 2 of the distortion voltage detecting electrode 16 is used.
The end 16 a on the side of the package 300 is connected to one output side detection terminal 50 on the tape carrier package 300. On the other hand, the liquid crystal display device of the second embodiment is connected to a plurality of detection terminals. FIG. 4 is a plan view showing a configuration of a main part of the liquid crystal display device according to the second embodiment. The output side detection terminals 50 and 2 are connected to the bridging pattern wiring 51 on the tape carrier package 300.
While the positioning dummy terminals 53 are connected in parallel, the ends 16 a of the strain voltage detection electrodes 16 in the liquid crystal display panel 100 are integrally connected to the lands 17 formed on the glass substrate 11. The output side detection terminal 50 and the two positioning dummy terminals 53 connected in parallel to the land 17 are joined. Also in the case of the second embodiment, the tape carrier package 300 is formed symmetrically. Other configurations are the same as those of the first embodiment, and therefore, the same reference numerals are given to corresponding portions, and
Description is omitted.

In this case, since the junction area is large, the contact resistance is reduced, the induced distortion voltage is further reduced, the voltage correction in the voltage correction circuit 29 is made more accurate, and the scanning non-selection voltage V _com is reduced. Crosstalk caused by the induced distortion voltage can be prevented with higher accuracy.

[Third Embodiment] FIG. 5 is a plan view showing a configuration of a main part of a liquid crystal display device according to a third embodiment. In the tape carrier package 300, the two positioning dummy terminals 53 are omitted, and the output side detection terminal 50 to be connected to the end 16a of the strain voltage detection electrode 16 is also used as the positioning dummy terminal. . In other words, it can be said that the positioning dummy terminal 53 is also used as the output side detection terminal 50 to be connected to the distortion voltage detection electrode 16. Also in the case of the third embodiment, the tape carrier package 300 is formed symmetrically. Note that the positioning dummy terminal 5
Only one of the three may be omitted, and one may be left as shown by a two-dot chain line. Similarly to the second embodiment, the output side detection terminal 50 may be connected in parallel to the positioning dummy terminal 53 left. Other configurations are described in Embodiment 1.
Therefore, the same reference numerals are given to the corresponding parts, and the description is omitted.

In each of Embodiments 1 to 3 described above, the uppermost scanning electrode of the extra scanning electrode group 12 # formed in the manufacturing process of the liquid crystal display panel 100 is replaced with the distortion voltage detecting electrode 16 Was configured to be used as
Depending on the position of the voltage correction circuit 29 on the scan-side printed circuit board 200a, one extra scan electrode group 12 is formed.
The lowermost scanning electrode of ‥ may be used as the strain voltage detecting electrode 16.

In order to make the distortion voltage detecting electrode 16 electrically equivalent to the scanning electrode 12 with respect to the induced distortion voltage, the distortion voltage detecting electrode 16 is not necessarily connected to the liquid crystal cell 15.
It is not necessary to connect ‥, and it is sufficient to have a capacitance component equivalent to that of the liquid crystal cell 15 ‥.

In the scan electrode power supply circuit 22, the buffer 25 for outputting the higher scanning selection voltage V _H and the buffer 27 for outputting the lower scanning selection voltage _VL are also _{supplied to the} scanning non-selection voltage V _com. May be connected to the same voltage correction circuit as the voltage correction circuit 29 provided for the buffer 26 that outputs the signal. These voltage correction circuits are also connected to the pattern wiring 33 on the printed circuit board 200a connected to the bridging pattern wiring 51.

The configuration of the voltage correction circuit 29 is not limited to that shown in the figure, but may be any configuration as long as it corrects the scanning voltage so as to reduce the detected distortion voltage. .

In each of the first to third embodiments, the output side connected to the input side detection terminal 49 via the bridging pattern wiring 51 in the tape carrier package 300 on the scanning side printed circuit board 200a side. The end 16a of the strain voltage detection electrode 16 is connected to the detection terminal 50. Alternatively or together with this, a strain voltage detection electrode that is electrically equivalent to the signal electrode 14 with respect to the strain voltage is connected to the signal electrode group 14. And a tape carrier package 30 on the signal side printed circuit board 200b side.
At 0, the end of the distortion voltage detection electrode may be connected to the output side detection terminal 50.

Further, the present invention relates to each of the above-described first to third embodiments.
The tape carrier package 300 itself used in the liquid crystal display devices of (1) to (3) is an object of the present invention as a single component.

[0050]

According to the liquid crystal display device of the first aspect of the present invention, in the liquid crystal display panel, a distortion voltage detecting electrode which is electrically equivalent to the scanning electrode with respect to the distortion voltage is provided in parallel with the scanning electrode. Since the detection electrode is connected to the voltage correction circuit via a bridging pattern wiring that is not connected to the liquid crystal drive IC on the tape carrier package, wiring for drawing out a distortion voltage such as a jumper wire is provided at the open end of the scanning electrode. Compared to the conventional technology, which connects and connects it to the voltage correction circuit, since the wiring is virtually eliminated and hardly affected by extraneous noise, the jumper wire that tends to be long tends to be long. This eliminates the problem that the detected distortion voltage is buried in extraneous noise as in the case of It is possible to reliably suppress the talk. In addition, there is no need to prepare wiring materials such as jumper wires, and there is no need for complicated wiring work and wiring work for the scanning electrode open side end and voltage correction circuit, and the tape carrier package for the liquid crystal display panel is eliminated. Since the strain voltage detecting electrode can be connected to the bridging pattern wiring at the same time as the bonding, there is no unnecessary increase in the number of steps and no cost increase.

According to the tape carrier package for a liquid crystal display device according to the second aspect of the present invention, the distortion voltage detecting electrode provided on the liquid crystal display panel is electrically equivalent to the scanning electrode with respect to the induced distortion voltage. When connecting the voltage correction circuit provided on the printed circuit board, a liquid crystal driving IC for connecting the electrode voltage power supply circuit of the printed circuit board and the scanning electrode of the liquid crystal display panel is mounted and a liquid crystal for bridging the printed circuit board and the liquid crystal display panel. In the display device tape carrier package itself, the strain voltage detection electrode and the voltage correction circuit are connected via the bridging pattern wiring formed on the tape carrier, so that the liquid crystal display device tape carrier package is used. By doing
When manufacturing a liquid crystal display device by assembling a printed circuit board and a liquid crystal display panel, a wiring for drawing out a distortion voltage such as a jumper wire was connected to the open end of the scanning electrode, and it was routed and connected to a voltage correction circuit. Compared to the conventional technology, the wiring is virtually eliminated, and there is almost no influence from external noise.Therefore, the detected distortion voltage is buried in the external noise as in the case of jumpers, etc., where the wiring tends to be long. The distortion voltage can be corrected accurately and the crosstalk can be suppressed reliably, and there is no need to prepare a wiring material such as a jumper wire. There is no need for complicated wiring work and wiring work for the voltage correction circuit, and the Since the bonding at the same time the distortion voltage detecting electrode of the carrier package can be connected to the bridge pattern lines, there is no wasted man-hours increase, need not incur the cost up.

According to the tape carrier package for a liquid crystal display device according to the third aspect of the present invention, since there are a plurality of output-side detection terminals, the junction area with the end of the strain voltage detection electrode can be increased, and the contact resistance can be reduced. Thus, the distortion voltage induced by the distortion voltage can be further reduced, the voltage correction in the voltage correction circuit can be made more accurate, and the crosstalk caused by the distortion voltage can be prevented with higher accuracy.

According to the tape carrier package for a liquid crystal display device according to the fourth aspect of the present invention, since the output side detection terminal is also used as the positioning dummy terminal, the configuration for suppressing crosstalk is simplified and inexpensive. It can be realized with something simple.

According to the tape carrier package for a liquid crystal display device according to the fifth aspect of the present invention, the entire structure including the liquid crystal driving IC is symmetrical, so that the liquid crystal driving IC is placed on the front side depending on the model. In some cases, the liquid crystal display panel is connected to the liquid crystal display panel and the liquid crystal display panel is connected with the liquid crystal drive IC on the back side. Either one can be selected and used, simplifying the work of arranging the wiring for extracting the distortion voltage required to suppress the crosstalk described above, and shortening the wiring as much as possible to reduce the influence of external noise. It is possible to exhibit the effect of making it hard to receive and to surely suppress the crosstalk.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing a schematic circuit configuration of a liquid crystal display device according to a first embodiment of the present invention.

FIG. 2 is a plan view showing a configuration of a tape carrier package used in the first embodiment.

FIG. 3 is an enlarged plan view of a main part specifically showing a state of connection between a strain voltage detection electrode of a liquid crystal display panel and a pattern wiring from a voltage correction circuit of a printed circuit board with respect to a bridging pattern wiring on a tape carrier package. is there.

FIG. 4 is a plan view showing a configuration of a main part centering on a tape carrier package used in a liquid crystal display device according to a second embodiment of the present invention.

FIG. 5 is a plan view showing a configuration of a main part mainly of a tape carrier package used in a liquid crystal display device according to a third embodiment of the present invention.

FIG. 6 is a waveform chart for explaining the operation.

[Explanation of symbols]

12 ... scanning electrode 14 ... signal electrode 15 ... liquid crystal cell 16 ... distortion voltage detection electrode 16 a ... end of distortion voltage detection electrode 17 ... land 22 ... scan electrode power supply circuit 23 ... signal electrode power supply circuit 25 ...... outputs a higher scanning selection voltage V _L becomes a buffer 27 ...... lower operational amplifier for outputting a buffer 26 ...... scanning non-selection voltage V _com to an operational amplifier for outputting a scanning selection voltage V _H of the operational Buffer composed of amplifier 29 Voltage correction circuit 33 Pattern wiring on printed circuit board connected to voltage correction circuit 41 Tape carrier 42 Input terminal group 43 Output terminal group 45 Liquid crystal drive IC 45x Signal Drive IC 45y Scanning drive IC 49 Input-side detection terminal 50 Output-side detection terminal 51 Bridge pattern wiring 52 Positioning device H 53... Positioning dummy terminal 100... Liquid crystal display panel 200a... Scanning side printed circuit board 200b... Signal side printed circuit board 300... Tape carrier package 500... Distortion such as jumper wires used in the prior art. Wiring for voltage extraction

Claims (5)

[Claims] 1. A liquid crystal display panel in which a plurality of scanning electrodes and a plurality of signal electrodes are arranged to face each other in a matrix in a state of being orthogonal to each other, and a liquid crystal cell is arranged at each intersection, and a print on which an electrode voltage power supply circuit is mounted. And a tape carrier package mounted with a liquid crystal driving IC connected to the output side of the electrode voltage power supply circuit and bridging between the liquid crystal display panel and the printed board, and connected to the scanning electrode, In the liquid crystal display panel, a strain voltage detection electrode which is electrically equivalent to the scan electrode and parallel to the scan electrode with respect to a strain voltage induced in the scan electrode in the non-selection period due to the signal voltage waveform immediately outside the scan electrode group. Is disposed, and a distortion voltage induced by the distortion voltage detection electrode is supplied to an electrode voltage power supply circuit that supplies a voltage to a scanning electrode on the printed circuit board. In a liquid crystal display device provided with a voltage correction circuit for correcting a supply voltage by inputting in a negative feedback manner,
On the tape carrier package, the distortion voltage detection electrode of the liquid crystal display panel is connected to the bridging pattern wiring formed from the input edge to the output edge in a state of being disconnected from the liquid crystal drive IC on the tape carrier package. The liquid crystal display device, wherein an end is connected, and a pattern wiring connected to the voltage correction circuit on the printed circuit board is connected to the bridging pattern wiring on the tape carrier package. 2. A plurality of scanning electrodes and a plurality of signal electrodes are opposed to each other in a matrix in a state of being orthogonal to each other, a liquid crystal cell is arranged at each intersection, and a signal voltage waveform is provided immediately outside the scanning electrode group. A liquid crystal display panel provided with a strain voltage detection electrode that is electrically equivalent to the scan electrode and is parallel to the scan electrode with respect to a strain voltage induced by the scan electrode during the non-selection period, and an electrode voltage that supplies a voltage to the scan electrode A bridge between a power supply circuit and a printed circuit board on which a voltage correction circuit for correcting a supply voltage by negatively inputting a distortion voltage induced by the distortion voltage detection electrode to the power supply circuit and correcting the supply voltage is provided. A tape carrier package on which a liquid crystal driving IC connected to the output side of the electrode voltage power supply circuit and connected to the input side of the scanning electrode is mounted on the tape carrier. In the tape carrier, an input side detection terminal for connecting to a pattern wiring connected to a voltage correction circuit of the printed circuit board and an output side for connecting to an end of a distortion voltage detection electrode of the liquid crystal display panel. A tape carrier package for a liquid crystal display device, wherein a bridging pattern wiring is formed in a state of being disconnected from the liquid crystal drive IC over a detection terminal. 3. A liquid crystal display panel connected to an input-side detection terminal for connection to a pattern wiring connected to a voltage correction circuit of a printed circuit board via a bridging pattern wiring in a state of not being connected to a liquid crystal driving IC. 3. The tape carrier package for a liquid crystal display device according to claim 2, wherein a plurality of output side detection terminals connected to the end of the distortion voltage detection electrode are provided. 4. The liquid crystal display panel according to claim 2, wherein an output-side detection terminal connected to an end of the distortion voltage detection electrode is also used as a positioning dummy terminal near the positioning mark. A tape carrier package for a liquid crystal display device according to the above. 5. The liquid crystal display according to claim 2, wherein the entire structure including the liquid crystal driving IC is symmetrical.
The tape carrier package for a liquid crystal display device according to any one of the above.